DE3311022C2 - - Google Patents

Description

The invention relates to a circuit breaker with a fixed Main contact and a movable main contact, with a the first main contact assigned to the fixed main contact and a second fixedly connected to the movable main contact Arch contact, with one over a resistor with the fixed main contact connected resistance electrode and with an electrically conductive screen that has a circular opening has behind which the fixed main contact and the an arch contact are arranged.

The disconnector is usually found at substations near an associated circuit breaker and will commonly used to (1) one from the circuit breaker open and close separate line, and (2) transmission systems to switch. In the first case (1) the  Disconnect switch for opening and closing an unloaded electrical line, and it is known that the Relighting an electric arc between one Pair of opposite contact pieces of the disconnector repeated so that so-called surge peaks be generated. This is because the disconnector in the A relatively low comparison to the circuit breaker Has switching speed. It is also known that one equips the disconnector with an additional resistor, to such voltage surges when opening and Suppress closing.

On the other hand, the second case (2) is about using the Disconnector in the assigned busbar substation connect with each other. If, for example a pair of busbars with a common line is connected via appropriate disconnector, so leads the process of switching from one busbar to another to interrupt the so-called loop current, which is roughly one including through a circuit corresponds to the nominal current flowing in the pair of disconnectors, by having the good break property used, which has sulfur hexafluoride (SF₆). This is well known.

Furthermore, both the ability to be an unencumbered Opening and closing line as well as the ability to the loop current in the manner described above to open and close, in many cases for one common disconnector required in a substation to be ordered.

A disconnector of the type mentioned is from the CH-PS 4 00 294 known, but has some disadvantages in operation, which, for example, consists in the fact that at the moment an electrical arc between these two main contacts will arise. Only then will there be an arc between the one  Form the arch contact and the movable main contact, that only after the supply of the extinguishing gas Opening process occurs and is then deleted again. In addition, in the disconnector described there is a additional resistance electrode in the form of a cross to the Main contacts movable pin provided, the Resistance electrode over its resistance when switched off to form a Auxiliary arc is used. This resistance electrode however, requires an additional complicated plunger assembly for their activity.

Another conventional circuit breaker with a resistor to suppress voltage surges when opening and closing is for example in JP-OS 95 276/1978 described. The disconnector has a sulfur hexafluoride (SF₆) gas-filled housing, an extensive, electrically conductive support member, which is through one end of the Housing is sealed, as well as a stationary main contact and a stationary arch contact that is coaxial are arranged on the support part. It is also a hollow cylindrical one Resistor arranged on the support part, which is the stationary Main contact surrounds and has a free end part, which on a metal screen in the form of a half toroid ends, which is above the stationary main contact located and surrounds the stationary arch contact. A movable contact piece in the form of a hollow cylinder arranged so that it is the stationary main and arch contacts opposite and with these in separable engagement comes with one of its ends separable and sandwich-like is arranged between them.

When separating the movable contact part from the stationary one Main and arch contacts will be a variety of reignited electrical arc intermittently between the screen and the end of the moving contact caused the occurrence of high voltage surges lead which with the hollow cylindrical resistor be reduced. This applies to the case of  Intervention from moving contact with the stationary Main and arch contacts. In addition, the re-ignited Arc to damage the screen.

Furthermore, a near the cylindrical resistor trained electric field changed abruptly, namely immediately after the appearance of a re-ignited electrical Arc compared to the trained Field before the reignited arc occurs. This leads to a rapid increase in the field strength of the electric field from the screen or support to Housing is directed. This can increase the rapid the field strength of the electric field with a high probability develop into a ground fault.

The object of the invention is to provide an isolating switch Specify the type mentioned, with simple means has a good working order and with which Damage from the arc, especially when Reignition can be largely avoided.

The solution according to the invention is a disconnector of the type in question so that in closed state of the switch the pair of arch contacts is in contact with one another that the fixed main contact assigned arch contact in the direction on the movable main contact along a predetermined Track movable and in this direction by a spring arrangement is prestressed, the predetermined distance is dimensioned so that when the switch is opened first Main contacts and then open the arch contacts that the electrically conductive shield formed as a closed capsule that completely surrounds the fixed main contact, and that the resistance electrode is annular and essentially concentric to the annular Opening as well as in the distance between the screen and the Movable arch contact is arranged and one from the Has opening protruding surface so that the  Arch contacts in parallel at the moment of separation to a series connection of resistance and a gap between the resistance electrode and the one with the movable one Main contact connected arc contact are switched.

In a further development of the disconnector according to the invention provided that the resistance electrode in the form of a Toroids trained and electrically using support rods connected to the resistance.

Furthermore, it proves useful if the fixed main contact assigned arc contact spherical trained and coaxial against the annular arc contact of the movable main contact can be pressed.

In a further development of the disconnector according to the invention provided that the assigned to the fixed main contact Arch contact has a slidably mounted support rod, the one with a compression spring towards the opposite Arch contact is biased.

In this embodiment, it proves expedient if a spring housing is assigned to the fixed main contact is that receives the compression spring and in which the support rod is movable over a predetermined distance.

In a further development of the disconnector according to the invention provided that the movable main contact from a fixed screen is surrounded by a pair of opposite openings concentric to the housing of the Isolator switch and the electrically with the movable Main contact is connected.

From the above it follows that according to the invention, a circuit breaker is specified, the one resistance electrode arranged independently within the screen and one located inside the screen Exhibits resistance. In the disconnector according to the invention  prevents the electrical insulation property deteriorated towards earth in the event of an interruption. If, in addition, the resistance electrode is made of an arc-resistant or solid material to Example of a copper-tungsten alloy or carbon, so damage is suppressed and the movable contact pieces have better dielectric strength.

The invention is described below with reference to the description of embodiments and with reference to the enclosed drawing explained in more detail. The drawing shows in:

Figure 1 is a longitudinal section of an embodiment of the circuit breaker in its closed position, with some parts shown in side view.

FIG. 2 shows a perspective illustration of the stationary contact side of the disconnector according to FIG. 1, partially with cutouts;

Fig. 3 is a partial longitudinal section of a part of the circuit breaker of Figure 1, with parts shown in side view.

Of the movable contact, until the fully open position reached 4 to 6 are similar to Figure 3 are views for explaining the successive positions relative to the fixed contact after the disconnecting switch shown in Figure 1, the opening operation has been initiated...;

FIG. 7 shows an equivalent circuit diagram of the disconnector according to FIG. 1 when a loop current is interrupted;

FIG. 8 shows a representation similar to FIG. 5 or 6 to explain the position of the movable contact relative to the fixed contact pieces shortly before the fully open position; and in

FIG. 9 shows an equivalent circuit diagram of the disconnector according to FIG. 1 when an unloaded electrical line is opened.

In Fig. 1, an embodiment of the circuit breaker is shown according to the invention. The disconnector shown has a housing 100 in the form of a hollow metallic cylinder, which is formed at one end, in this case at the left end in the illustration according to FIG. 1, and is closed with an electrically insulating cover 102 , as an electrically conductive part 104 Support part, which runs centrally and extends sealed through the electrically insulating cover 102 , and an electrically conductive screen 106 in the form of a hollow cylinder which is arranged within the housing 100 and is formed coaxially to the longitudinal axis thereof. The screen 106 consists of a part, in this case a left part, which is connected to the electrically conductive part 104 at the left end in the illustration according to FIG. 1, and another part which is connected at the left end in the illustration according to FIG. 1 is attached to the right end of the left part with a radially inward flange and which at the other or right end part merges into a half ring or a toroidal part with a curved or curved surface which projects at a distance from the main body of the screen 106 and a circular Opening 106 a forms.

An electrically conductive part 108 in the form of a strip is electrically connected to the flange of the screen 106 , both ends of which are connected to the flange (cf. FIG. 2). The electrically conductive part 108 runs perpendicular to the longitudinal axis of the housing 100 and is connected in the central region to an electrically conductive spring housing 110 in the form of a hollow cylinder which extends in the longitudinal axis of the housing 100 and the end at a distance from the electrically conductive part 108 , in in this case, the left end according to FIG. 1, which is recessed or undercut.

The spring housing 110 is connected at its left end to an electrically conductive strip 112 , which runs parallel to the electrically conductive part 108 , but is oriented perpendicular to the latter in plan view. In addition, a pair of resistors 114 are arranged at the two ends of the electrically conductive strip 112 , which run parallel to the longitudinal axis of the housing 100 (see FIGS. 1 and 2). Each of these resistors 114 consists of a stack of stacked resistor elements 114 a in the form of disks, which have an electrically insulating rod 114 b , which extends through them and the resistor elements 114 a together to form an integral arrangement with a metallic disk at the end connects. The pair of resistors 114 is c via a pair of metal support rods 114 having a toroidal or annular resistor electrode 116 connected, which is arranged within the opening of the screen 106 so that they are substantially at the same height as the reentrant or folded peripheral end of the shield 106 is located.

The electrically conductive part 108 is provided on its surface remote from the spring housing 110 with a raised area in the form of a fixed cylinder and a plurality of electrically conductive contact fingers, which are arranged radially at equal angular intervals around the raised area of the electrically conductive part 108 and with their ends are attached to this. Thus, the plurality of contact fingers form a stationary main contact 118 , which is connected to the electrically conductive part 108 .

In addition, an electrically conductive support rod 120 extends movably through the central regions of the electrically conductive part 108 and the spring housing 110 so that it lies in the longitudinal axis of the housing 100 , and is at its right end in the illustration according to FIG. 1 with a stationary Provide arch contact 122 in the form of a spherical segment, which consists of arc-resistant or solid material. The stationary arch contact 122 is electrically connected to the screen 106 via the support rod 120 , the spring housing 110 and the electrically conductive part 108 .

In addition, a coil spring or coil spring 124 is disposed within the spring housing 110 between the left end and connected to the support rod 120 spring holder, to try to normally urge the stationary arc contact 122 toward the opening 106 a of the screen 106th In the in Fig. Open position shown in Figure 5, the spring holder abuts against the electrically conductive part 108 to be arranged around the stationary arcing contact 122 slightly above the free end of the stationary main contact 118 and substantially in the plane defined by the circular opening 106 a of the Screen 106 is formed.

As shown in Fig. 1, an electrically conductive screen 120 a is arranged in the right half of the housing 100 in the illustration according to FIG. 1, which is connected at its lower end to an electrically conductive part 122 a , which is central and sealed extends through an electrically insulating cover 124 a , which hermetically seals the lateral opening of the housing. The screen 120 a consists of a pair of screen parts, which are connected via a pair of radially inwardly directed flanges, which are arranged at their adjacent ends, extend perpendicular to the longitudinal axis of the housing 100 and are fastened to one another.

The screen 120 a is provided with a pair of opposite openings concentric to the longitudinal axis of the housing 100 . In addition, a cylinder 126 made of electrically conductive material is connected to the interconnected flanges of the screen 120 a via a radially outwardly extending flange and has a piston 128 which is slidably arranged in the cylinder 126 so that it extends coaxially to the longitudinal axis of the housing 100 . The piston 128 is made of electrically conductive material and is connected to a movable main contact 130 which extends along the longitudinal axis of the housing 100 to the stationary main contact 118 and has a movable arch contact 132 in the form of a ring which is arranged at its end. The movable main contact 130 has a flow guide 130 a , which is connected to the interior of the cylinder 126 .

The piston 128 is connected to an actuating rod 134 made of electrically insulating material, which extends in the longitudinal axis of the housing 100 so that it is arranged at a distance therefrom, and is then connected to a drive source, not shown, via a linkage 136 , which is arranged in a drive compartment at the other end of the housing 100 so that it communicates with the interior. The housing 100 is with an arc quenching gas, for. B. gaseous sulfur hexafluoride (SF₆) filled.

As shown in FIGS. 1 and 4, the movable main contact 130 is arranged so that it communicates with the main stationary contact 118 to form a pair of main contacts 138 in engagement (see. Fig. 3), while the movable arc contact 132 arranged so is that it engages the stationary arch contact 122 to form a pair of arch contacts 140 (see FIG. 3). The pair of arch contacts 140 are arranged to be brought into their open position after the pair of main contacts 138 have been separated.

The mode of operation of the arrangement according to FIG. 1 is explained in more detail below. In Fig. 1, the movable arc contact 132 is shown as it, is adjacent to the annular end of the fixed arcing contact 122, and at its portion on the periphery, to the movable main contact 130 to the inside of the fixed main contact 118 in engagement with the helical spring 124 is brought into its compressed state. If a loop current is interrupted in the manner described above with the circuit breaker according to FIG. 1, the electrically insulating rod 134 is moved in the representation of FIG. 1 by the operation of the linkage 136 to the right to the movable main contact 130 to the fixed main contact 118 disengage. This leads to a rightward movement of the fixed main contact 118 due to the action of the coil spring 124 . Thus, the movable and fixed main contacts 118 and 130 assume their positions according to FIG. 4. At this time, the pressure within cylinder 126 is reduced to create a pressure difference between housing 100 and cylinder 126 .

During the rightward movement of the movable main contact 130, the separation of the movable arc contact 132 is released from the fixed arcing contact 122, so that the loop current proposes an electric arc 142 between the contacts 122 and 132, as shown in Fig. 5. This electric arc 142 can be extinguished by using a gas flow due to the pressure difference between the housing 100 and the cylinder 126 .

The main movable contact 130 continues its rightward movement. Since a recovery voltage generated when the loop current is interrupted is typically on the order of a few hundred volts, the electric arc does not re-ignite after the loop current is interrupted, and the movable arcing contact 132 finally reaches its position shown in FIG leads to the termination of the interruption process.

FIG. 7 shows an equivalent circuit diagram to explain the state in which the loop current is interrupted. The arrangement shown is provided with the isolating switch, which is represented by a parallel connection of current paths, namely a current path which has the movable main contact 122 , the fixed main contact 118 and a gap between the two main contacts 122 and 118 ; a current path which has the movable arcing contact 132 , the fixed arcing contact 122 , the arc 142 struck between the two arcing contacts 132 and 122 and the electrically conductive part 108 ; and a current path comprising the movable arch contact 132 , the resistance electrode 116 , a gas path between the movable arch contact 132 and the resistance electrode 116 , the resistor 114 with a resistance value R and the spring housing 110 . The parallel connection is connected at one end to the electrically conductive arch contact 122 and at the other end to the electrically conductive part 104 via the screen 106 . In addition, the electrically conductive arch contact 122 is connected to the electrically conductive part 104 via a current path, via which the loop current i flows from the electrically conductive arch contact 122 to the electrically conductive part 104 .

From Fig. 7 it follows that when the loop current is interrupted, the current path goes solely via the two arcing contacts 122 and 132 .

Then opening an unloaded electrical Management described. The operation of the disconnector itself is self-evident in the interruption of the loop current and the opening of an unloaded Line identical, but the phenomena that occur in Disconnect the moving contacts from the fixed contacts develop are different.  

As discussed above, the electrically isolating actuator rod 134 is moved to the right to first disengage the main movable contact 130 from the main fixed contact 118 and then to disengage the movable arch contact 132 from the fixed arch contact 122 . At this point in time, a potential difference develops between the arch contacts 122 and 132 , since an electrical voltage source (not shown) assigned to the electrical line oscillates at a normal frequency. As a result, an electric arc is struck again between these arcing contacts 122 and 132 .

The re-ignited electric arc causes a surge, which generally has an extremely large amplitude value, which is a value from 1.7 to 1.9 times. Such a surge is generally proportional to a potential difference between the contacts when the electric arc is re-ignited. The potential difference is also proportional to a distance between the contact pieces. Thus, a surge that must be suppressed by the insertion of a resistor is limited to what is caused in a position where the main movable contact 130 is a certain distance away from the fixed arc contact 122 . This distance depends on the type of device and is not less than about a quarter to about a third of the maximum distance by which the movable main contact 130 can be separated from the fixed arch contact 122 in the fully open position.

Accordingly, it is not necessary to suppress a surge due to an electric arc that has reignited between the main movable contact 130 and the fixed arcing contact 122 by inserting a resistor. When the main movable contact 130 reaches its position according to FIG. 8, this position being at a distance from the fixed arcing contact 122 which is approximately equal to one third to half of the maximum distance specified above, an electric arc 144 is again between the movable arcing contact 132 and the resistance electrode 116 ignited. The re-ignited electric arc 144 can create a potential difference between the arc contact 132 and the resistance electrode 116 that can be as high as 2 pu, which is twice the peak value of a normal voltage to ground. Thus, a surge due to this reignited arc is extremely large. Accordingly, it is necessary to incorporate a resistor in series with the circuit breaker circuit to suppress the surge.

However, the fixed arc contact 122 is located within the screen 106 away from the plane of the opening 106 a compared to the annular resistance electrode 116 , and a gap is formed between the opening 106 a of the screen 106 and the resistance electrode 116 . Under these circumstances, all electric arcs can reignite between the movable arcing contact 132 and the resistance electrode 116 . In addition, due to the gap between the opening 106 a and the resistive electrode 116 of the re-ignition electric arc within a range move, which is limited to the surface area of the resistive electrode 116, opposite to the movable arc contact 132 without the sheet screen the screen 106th This means that the re-ignited electric arc can hardly interfere with a potential distribution that has formed in the vicinity of the screen 106 and the screen 120 a . Thus, the re-ignited electric arc has only an extremely small possibility of developing into an earth fault.

FIG. 9 shows an equivalent circuit diagram to explain the state of the electric arc which has reignited when the unloaded line according to FIG. 8 is opened. The arrangement differs from that according to FIG. 7 only in that in FIG. 9 the electric arc 144 has reignited between the movable arcing contact 132 and the resistance electrode 116 without the electric arcing 142 having reignited between the arcing contacts 132 and 122 , and that the current path for direct connection of the arch contact 122 and the electrically conductive part 104 is omitted.

From Fig. 9 that, when the movable main contact 8 is 132 in its position shown in Fig., The resistor 114 suppresses a harmful voltage surge which develops 104 and the arcing contact 122 between the electrically conductive part is obtained. This is because all of the voltage surges due to the re-ignited electric arc pass through the resistor 114 .

At this time, the potential difference Vp is formed , which is related to the following equation

expresses, over the respective resistor 114 . Suitable electrically insulating distances are therefore required, which are to be provided between the resistance electrode 116 and the screen 106 and between the respective support rod 114 c and the electrically conductive part 108 .

However, the potential difference Vp is formed across each resistor in the surge energy consumption process. Assuming that the electrical insulation breaks down in a space located between the screen 106 and one end of one of the resistors 114 , the voltages across the resistors 114 are only equal to each other, but a potential distribution between the screen 106 and the housing 100 is not changed. Thus, the circuit breaker maintains the electrical insulation property from earth, which is its primary function and is not suppressed.

After the main movable contact 130 has been brought into an electrically insulating distance which can sufficiently withstand a potential difference of, for example, 2 pu, which is formed between the contacts 118 and 130 , the re-ignited electric arc occurs. The movable main contact 130 is then moved further and brought into its fully open position, as shown in FIG. 6.

Claims (6)

1. isolating switch, with a fixed main contact ( 118 ) and a movable main contact ( 130 ),
with a first arcing contact ( 122 ) assigned to the fixed main contact ( 118 ) and a second arcing contact ( 132 ) fixedly connected to the movable main contact ( 130 ),
with a resistance electrode ( 116 ) connected via a resistor ( 114 ) to the fixed main contact ( 118 ), and with an electrically conductive screen ( 106 ) which has a circular opening ( 106 a) , behind which the fixed main contact ( 118 ) and which an arcing contact ( 122 ) are arranged,
characterized,
that in the closed state of the switch, the pair of arch contacts ( 122, 132 ) are in contact with one another, that the arch contact ( 122 ) assigned to the fixed main contact ( 118 ) is movable in the direction of the movable main contact ( 130 ) along a predetermined distance and in this Direction is biased by a spring arrangement ( 110, 124 ), the predetermined distance being dimensioned such that when the switch is opened first the main contacts ( 118, 130 ) and then the arch contacts ( 122, 132 ) open,
that the electrically conductive shield ( 106 ) is designed as a closed capsule which completely surrounds the fixed main contact ( 118 ),
and that the resistance electrode ( 116 ) is annular and is arranged essentially concentrically to the annular opening ( 106 a) and at a distance between the screen ( 106 ) and the movable arc contact ( 122 ) and has a surface protruding from the opening ( 106 a) , so that the arc contacts ( 122, 132 ) at the moment of separation from one another are connected in parallel to a series circuit comprising a resistor ( 114 ) and a gap between the resistance electrode ( 116 ) and the arc contact ( 132 ) connected to the movable main contact ( 130 ). 2. Disconnector according to claim 1, characterized in that the resistance electrode ( 116 ) is designed in the form of a toroid and is electrically connected to the resistor ( 114 ) via support rods ( 114 c) . 3. Disconnector according to claim 1 or 2, characterized in that the fixed main contact ( 118 ) associated arc contact ( 122 ) is spherical and can be pressed coaxially against the annular arc contact ( 132 ) of the movable main contact ( 130 ). 4. Disconnector according to one of claims 1 to 3, characterized in that the fixed main contact ( 118 ) associated arc contact ( 122 ) has a displaceably mounted support rod ( 120 ) with the compression spring ( 124 ) in the direction of the opposite arc contact ( 132 ) is biased. 5. Disconnector according to claim 4, characterized in that the fixed main contact ( 118 ) is assigned a spring housing ( 110 ) which receives the compression spring ( 124 ) and in which the support rod ( 120 ) is movable over a predetermined distance. 6. Disconnector according to one of claims 1 to 5, characterized in that the movable main contact ( 130 ) is surrounded by a fixed screen ( 120 a) which has a pair of opposite openings concentric to the housing ( 100 ) of the disconnector and the is electrically connected to the movable main contact ( 130 ).